Hostname: page-component-586b7cd67f-dsjbd Total loading time: 0 Render date: 2024-11-29T07:08:58.471Z Has data issue: false hasContentIssue false

Integrated Assessment of Environmental Effects from Agricultural Production

Published online by Cambridge University Press:  10 May 2017

John G. Lee
Affiliation:
Department of Agricultural Economics, Purdue University, West Lafayette, IN
Stephen B. Lovejoy
Affiliation:
Department of Agricultural Economics, Purdue University, West Lafayette, IN
Get access

Abstract

Agriculture's impact on the environment is a complex research problem. A challenge to future economic research is to account for the interrelationship between agricultural production activities, soil productivity, erosion, and water quality. It will become increasingly important to determine not only the economic consequences, but also the environmental effectiveness of alternative policies aimed at improving resource use and quality. The application of biophysical simulation models to environmental quality problems provides a means to better understand the complex interaction between agricultural production and environmental quality.

Type
The Effects of Agricultural Production on Environmental Quality
Copyright
Copyright © 1991 Northeastern Agricultural and Resource Economics Association 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Footnotes

Approved as Journal Paper No. 12743 of the Agricultural Experiment Station, Purdue University.

References

Beasley, D. B., Huggins, L. F., and Monke, E. J.ANSWERS: A Model for Watershed Planning.” Trans. Amer Soc. Agr. Eng. 23 (1980):938–44.Google Scholar
Braden, J. B., Johnson, G. V., Bouzaher, A., and Miltz, D.Optimal Spatial Management of Agricultural Pollutants.” American Journal of Agricultural Economics 71 (1989):404–13.Google Scholar
Burt, R. O.Farm Level Economics of Soil Conservation in the Palouse Area of the Northwest.” American Journal of Agricultural Economics 63 (1981):8392.Google Scholar
Dillon, C. R., Mjelde, J. W., and McCarl, B. A.Biophysical Simulation in Support of Crop Production Decisions: A Case Study in the Blacklands Region of Texas.” Southern Journal of Agricultural Economics (1989):7386.Google Scholar
Foltz, J. C., Martin, M. A., and Lowenberg-DeBoer, J.Low Input Sustainable Agriculture: Economic and Environmental Implications of Increased Alfalfa Production in the Eastern Corn Belt.” Selected paper presented at the annual meeting of the American Agricultural Economics Association 4–8 August 1990, Vancouver, BC.Google Scholar
Harris, T. R., and Mapp, H. P.A Stochastic Dominance Comparison of Water-Conserving Irrigation Strategies.” American Journal of Agricultural Economics 68 (1986):298305.Google Scholar
Huszar, P. C.Economics of Reducing Off-Site Costs of Wind Erosion.” Land Economics 65 (1989):333–40.Google Scholar
Lake, J., and Morrison, J., eds. Environmental Impact of Land Use on Water Quality. Final report of Phase Two of the Black Creek project, U.S.E.P.A. Project #95-9-81-003. Washington, DC: U.S. Government Printing Office, 1981.Google Scholar
Lee, J. G., Bryant, K. J., and Lacewell, R. D.Crop Rotation Selection Versus Wind Erosion Susceptibility.” Journal of Soil and Water Conservation 44 (1989):620–24.Google Scholar
Lee, J. G., Lovejoy, S. B., and Beasley, D. B.Soil Loss Reduction in Finley Creek, Indiana: An Economic Analysis of Alternative Policies.” Journal of Soil and Water Conservation 40 (1985):132–35.Google Scholar
Mapp, H. P., and Eidman, V. R.A Bioeconomic Simulation Analysis of Regulating Groundwater Irrigation.” American Journal of Agricultural Economics 58 (1976):391402.Google Scholar
Miranowski, J. A.Impacts of Productivity Loss on Crop Production and Management in a Dynamic Economic Model.” American Journal of Agricultural Economics 66 (1984):6171.Google Scholar
Moore, W. B., and McCarl, B. A.Off-Site Costs of Soil Erosion: A Case Study in the Willamette Valley.” Western Journal of Agricultural Economics 12 (1987):4249.Google Scholar
Musser, W. N., and Tew, B. V.Use of Biophysical Simulation in Production Economics.” Southern Journal of Agricultural Economics 16 (1984):7786.Google Scholar
National Research Council. “Economic Evaluation of Alternative Farming Systems.” In Alternative Agriculture, 195244. National Academy Press, 1989.Google Scholar
Pagoulatos, A., Debertin, D. L., and Sjarkowi, F.Soil Erosion, Intertemporal Profit, and the Soil Conservation Decision.” Southern Journal of Agricultural Economics (1989):5562.Google Scholar
Piper, S. L.Measuring the Particulate Pollution Damage from Wind Erosion in the Western United States.” Journal of Soil and Water Conservation 44 (1989):7075.Google Scholar
Ribaudo, M. O.Consideration of Offsite Impacts in Targeting Soil Conservation Programs.” Land Economics 62 (1986):402–11.Google Scholar
Saliba, B. C.Soil Productivity and Farmers’ Erosion Control Incentives—A Dynamic Modeling Approach.” Western Journal of Agricultural Economics 10(1985a):354–64.Google Scholar
Saliba, B. C.Irrigated Agriculture and Groundwater Quality—A Framework for Policy Development.” American Journal of Agricultural Economics 67 (1985b):1231–37.Google Scholar
Shortle, J. S., and Dunn, J. W.The Relative Efficiency of Agricultural Source Water Pollution Control Policies.” American Journal of Agricultural Economics 68 (1986):668–77.Google Scholar
Shortle, J. S., and Miranowski, J. A.Intertemporal Soil Resource Use: Is It Socially Excessive?Journal of Environmental Economics and Management 14 (1987):99111.Google Scholar
Taylor, D. B., and Young, D. L.The Influence of Technological Progress on the Long-Run Farm-Level Economics of Soil Conservation.” Western Journal of Agricultural Economics 10 (1985):6376.Google Scholar
U.S. Department of Agriculture. Soil Conservation Service. “Data for Decisions: 1982 National Resources Inventory.” Washington, DC, 1984.Google Scholar
Weisensel, W. P., and VanKooten, G. C.Estimation of Soil Erosion Time Paths: The Value of Soil Moisture and Topsoil Depth Information.” Western Journal of Agricultural Economics 15 (1990):6372.Google Scholar
Williams, J. R., Renard, K. G., and Dyke, P. T.EPIC: A New Method for Assessing Erosion's Effect on Soil Productivity.” Journal of Soil and Water Conservation 38 (1983):381–83.Google Scholar
Wischmeier, W. H., and Smith, D. D.Predicting Rainfall Erosion Losses—A Guide to Conservation Planning.” Agricultural Handbook number 537. U.S. Department of Agriculture. Washington, DC, 1978.Google Scholar